THIS WILL LIVE IN LEARNING VILLAGE
Rigorous Curriculum Design
Unit Planning Organizer
|Subject(s) |Math |
|Grade/Course |8th |
|Unit of Study |Unit 1: The Number System & Exponents |
|Unit Type(s) |❑Topical X Skills-based ❑ Thematic |
|Pacing |20 days |
| |
|Unit Abstract |
| |
|In this unit of study, students will apply the properties of exponents. They will represent very small or very large numbers in scientific |
|notation, perform operations and learn how to interpret when “E” appears on the calculator. Students will provide examples of linear equations|
|with one, infinitely many, or no solution. Students will understand that real numbers are rational or irrational; will place them on the |
|number line and compare them. |
| |
|Common Core Essential State Standards |
| |
|Domains: Expressions and Equations (8.EE), Number System (8.NS) |
| |
|Clusters: Work with radicals and integer exponents. |
|Analyze and solve linear equations. |
|Know that there are numbers that are not rational, and approximate them by |
|rational numbers. |
| |
|Standards: |
|8.EE.1 KNOW and APPLY the properties of integer exponents to GENERATE equivalent numerical expressions. For example: 32 × 3–5 = 3–3 = 1/33 =|
|1/27. |
| |
|8.EE.2 USE square root and cube root symbols to REPRESENT solutions to equations of the form x² = p and x³ = p, where p is a positive |
|rational number. EVALUATE square roots of small perfect squares and cube roots of small perfect cubes. KNOW that √2 is irrational. |
| |
|8.EE.3 USE numbers expressed in the form of a single digit times an integer power of 10 to ESTIMATE very large or very small quantities, and |
|to EXPRESS how many times as much one is than the other. For example, estimate the population of the United States as 3 × 108 and the |
|population of the world as 7 × 109, and determine that the world population is more than 20 times larger. |
| |
|8.EE.4 PERFORM operations with numbers expressed in scientific notation, including problems where both decimal and scientific notation are |
|used. USE scientific notation and CHOOSE units of appropriate size for measurements of very large or very small quantities (e.g., use |
|millimeters per year for seafloor spreading). Interpret scientific notation that has been generated by technology. |
| |
|8.EE.7 SOLVE linear equations in one variable. |
|a. Give examples of linear equations in one variable with one solution, infinitely many solutions, or no solutions. Show which of these |
|possibilities is the case by successively transforming the given equation into simpler forms, until an equivalent equation of the form x = |
|a, a = a, or a = b results (where a and b are different numbers). |
|b. Solve linear equations with rational number coefficients, including equation whose solutions require expanding expressions using the |
|distributive property and collecting like terms. |
| |
|8.NS.1 KNOW that numbers that are not rational are called irrational. UNDERSTAND informally that every number has a decimal expansion; for |
|rational numbers SHOW that the decimal expansion repeats eventually, and CONVERT a decimal expansion which repeats eventually into a rational |
|number. |
| |
|8.NS.2 USE rational approximations of irrational numbers to COMPARE the size of irrational numbers, LOCATE them approximately on a number line|
|diagram, and ESTIMATE the value of expressions (e.g., π2). For example, by truncating the decimal expansion of √2, show that √2 is between 1 |
|and 2, then between 1.4 and 1.5, and explain how to continue on to get better approximations. |
| |
|Standards for Mathematical Practice |
| |
|1. Make sense of problems and persevere in solving them. |
|2. Reason abstractly and quantitatively. |
|3. Construct viable arguments and critique the reasoning of others. |
| |
|4. Model with mathematics. |
|5. Use appropriate tools strategically. |
|6. Attend to precision. |
|7. Look for and make use of structure. |
|8. Look for and express regularity in repeated reasoning. |
| |
| |
|Unpacked Standards |
|8.EE.1 In 6th grade, students wrote and evaluated simple numerical expressions with whole number exponents (i.e. 53 = 5 • 5 • 5 = 125). |
|Integer (positive and negative) exponents are further developed to generate equivalent numerical expressions when multiplying, dividing or |
|raising a power to a power. Using numerical bases and the laws of exponents, students generate equivalent expressions. |
| |
|Students understand: |
|Bases must be the same before exponents can be added, subtracted or multiplied. (Example 1) |
|Exponents are subtracted when like bases are being divided (Example 2) |
|A number raised to the zero (0) power is equal to one. (Example 3) |
|Negative exponents occur when there are more factors in the denominator. These exponents can be expressed as a positive if left in the |
|denominator. (Example 4) |
|Exponents are added when like bases are being multiplied (Example 5) |
|Exponents are multiplied when an exponents is raised to an exponent (Example 6) |
|Several properties may be used to simplify an expression (Example 7) |
| |
| |
|Example 1: |
|[pic] = [pic] |
|Example 2: |
| |
|[pic] = [pic] = [pic] = [pic] = [pic] |
| |
|Example 3: |
| |
|60 = 1 |
| |
|Students understand this relationship from examples such as [pic]. This expression could be simplified as [pic] = 1. |
| |
|Using the laws of exponents this expression could also be written as 62-2 = 60. Combining these gives 60 = 1. |
| |
| |
|Example 4: |
| |
|[pic]= [pic] x [pic] = [pic] x [pic] = [pic] x [pic] = [pic] |
| |
|Example 5: |
| |
|(32) (34) = (32+4) = 36 = 729 |
| |
|Example 6: |
| |
|(43)2 = 43x2 = 46 = 4,096 |
| |
|Example 7: |
| |
|[pic] [pic] [pic] [pic] [pic] |
| |
|8.EE.2 Students recognize perfect squares and cubes, understanding that non-perfect squares and non-perfect cubes are irrational. |
|Students recognize that squaring a number and taking the square root √ of a number are inverse operations; likewise, cubing a number and |
|taking the cube root ³√ are inverse operations. |
| |
|Example 1: |
| |
|4² = 16 and √16 = ±4 |
| |
|NOTE: (-4)²= 16 while -4² = -16 since the negative is not being squared. This difference is often problematic for students, especially with |
|calculator use. |
| |
|Example 2: |
| |
| |
| |
| |
|Note: there is no negative cube root since multiplying 3 negatives would give negative. |
| |
|This understanding is used to solve equations containing square or cube numbers. Rational numbers would have perfect squares or perfect cubes |
|for the numerator and denominator. In the standard, the value of p for square root and cube root equations must be positive. |
| |
|Example 3: |
| |
|Solve: x2 = 25 |
|Solution: [pic] = ±[pic] |
|x = ±5 |
|NOTE: There are two solutions because 5 • 5 and -5 • -5 will both equal 25. |
|Example 4: |
| |
|Solve: x2 = [pic] |
|Solution: [pic] = ±[pic] |
|x = ± [pic] |
|Example 5: |
| |
|Solve: x3 = 27 |
|Solution: [pic] = [pic] |
|x = 3 |
| |
|Example 6: |
| |
|Solve: x3 = [pic] |
|Solution: [pic] = [pic] |
|x = [pic] |
|Students understand that in geometry the square root of the area is the length of the side of a square and a cube root of the volume is the |
|length of the side of a cube. Students use this information to solve problems, such as finding the perimeter. |
| |
| |
|Example 7: |
| |
|What is the side length of a square with an area of 49 ft2? |
| |
|Solution: [pic] = 7 ft. The length of one side is 7 ft. |
| |
| |
|8.EE.3 Students use scientific notation to express very large or very small numbers. Students compare and interpret scientific notation |
|quantities in the context of the situation, recognizing that if the exponent increases by one, the value increases 10 times. Likewise, if the |
|exponent decreases by one, the value decreases 10 times. Students solve problems using addition, subtraction or multiplication, expressing the|
|answer in scientific notation. |
| |
|Example 1: |
| |
|Write 75,000,000,000 in scientific notation. |
|Solution: 7.5 x 1010 |
| |
|Example 2: |
| |
|Write 0.0000429 in scientific notation. |
|Solution: 4.29 x 10-5 |
| |
| |
|Example 3: |
| |
|Express 2.45 x 105 in standard form. |
|Solution: 245,000 |
| |
|Example 4: |
| |
|How much larger is 6 x 105 compared to 2 x 103 |
|Solution: 300 times larger since 6 is 3 times larger than 2 and 105 is 100 times larger than 103. |
| |
|Example 5: |
| |
|Which is the larger value: 2 x 106 or 9 x 105? |
|Solution: 2 x 106 because the exponent is larger |
| |
|8.EE.4 Students understand scientific notation as generated on various calculators or other technology. Students enter scientific notation |
|using E or EE (scientific notation), * (multiplication), and ^ (exponent) symbols. |
| |
|Example 1: |
| |
|2.45E+23 is 2.45 x 1023 and 3.5E-4 is 3.5 x 10-4 |
|NOTE: There are other notations for scientific notation depending on the calculator being used. |
|Students add and subtract with scientific notation. |
| |
|Example 2: |
| |
|In July 2010 there were approximately 500 million facebook users. In July 2011 there were approximately 750 million facebook users. How many |
|more users were there in 2011? Write your answer in scientific notation. |
| |
|Solution: |
|Subtract the two numbers: 750,000,000 - 500,000,000 = 250,000,000 → 2.5 x 108 |
| |
|Students use laws of exponents to multiply or divide numbers written in scientific notation, writing the product or quotient in proper |
|scientific notation. |
| |
| |
|Example 3: |
| |
|(6.45 x 1011)(3.2 x 104) = (6.45 x 3.2)(1011 x 104) Rearrange factors |
|= 20.64 x 1015 Add exponents, multiplying powers of 10 |
|= 2.064 x 1016 Write in scientific notation |
| |
|Example 4: |
| |
|3.45 x 105 = 3.45 x 105 – (-2) Subtract exponents when dividing powers of 6.7 x 10-2 6.7 |
|= 0.515 x 107 Write in scientific notation |
|= 5.15 x 106 |
| |
|Example 5: |
| |
|(0.0025)(5.2 x 104) = (2.5 x 10-3)(5.2 x 105) Write factors in scientific notation |
|= (2.5 x 5.2)(10-3 x 105) Rearrange factors |
|= 13 x 10 2 Add exponents when multiplying |
|powers of 10 |
|= 1.3 x 103 Write in scientific notation |
| |
|Example 6: |
| |
|The speed of light is 3 x 10 8 meters/second. If the sun is 1.5x 1011 meters from earth, how many seconds does it take light to reach the |
|earth? Express your answer in scientific notation. |
| |
|Solution: 5 x 102 |
|(light)(x) = sun, where x is the time in seconds |
|(3 x 10 8 )x = 1.5 x 1011 |
| |
|1.5 x 1011 |
|3 x 10 8 |
| |
|Students understand the magnitude of the number being expressed in scientific notation and choose an appropriate corresponding unit. |
| |
|Example 7: |
| |
|3 x 108 is equivalent to 300 million, which represents a large quantity. Therefore, this value will affect the unit |
| |
| |
|8.EE.7 Students solve one-variable equations including those with the variables being on both sides of the equals sign. Students recognize |
|that the solution to the equation is the value(s) of the variable, which make a true equality when substituted back into the equation. |
|Equations shall include rational numbers, distributive property and combining like terms. |
| |
|Example 1: |
| |
|Equations have one solution when the variables do not cancel out. For example, 10x – 23 = 29 – 3x can be solved to x = 4. This means that |
|when the value of x is 4, both sides will be equal. If each side of the equation were treated as a linear equation and graphed, the solution |
|of the equation represents the coordinates of the point where the two lines would intersect. In this example, the ordered pair would be (4, |
|17). |
| |
|10 • 4 – 23 = 29 – 3 • 4 |
|40 – 23 = 29 – 12 |
|17 = 17 |
| |
| |
| |
|Example 2: |
| |
|Equations having no solution have variables that will cancel out and constants that are not equal. This means that there is not a value that |
|can be substituted for x that will make the sides equal. |
|-x + 7 – 6x = 19 – 7x Combine like terms |
|-7x + 7 = 19 – 7x Add 7x to each side |
|7 ≠ 19 |
| |
|This solution means that no matter what value is substituted for x the final result will never be equal to each other. |
|If each side of the equation were treated as a linear equation and graphed, the lines would be parallel. |
| |
|Example 3: |
| |
|An equation with infinitely many solutions occurs when both sides of the equation are the same. Any value of x will produce a valid equation.|
|For example the following equation, when simplified will give the same values on both sides. |
|–[pic](36a – 6) = [pic](4 – 24a) |
|–18a + 3 = 3 – 18a |
| |
|If each side of the equation were treated as a linear equation and graphed, the graph would be the same line. |
| |
|Students write equations from verbal descriptions and solve. |
| |
|Example 4: |
| |
|Two more than a certain number is 15 less than twice the number. Find the number. |
| |
|Solution: |
|n + 2 = 2n – 15 |
|17 = n |
| |
|8.NS.1 Students understand that Real numbers are either rational or irrational. They distinguish between rational and irrational numbers, |
|recognizing that any number that can be expressed as a fraction is a rational number. The diagram below illustrates the relationship between |
|the subgroups of the real number system. |
| |
|[pic] |
| |
|Students recognize that the decimal equivalent of a fraction will either terminate or repeat. Fractions that terminate will have denominators |
|containing only prime factors of 2 and/or 5. This understanding builds on work in 7th grade when students used long division to distinguish |
|between repeating and terminating decimals. |
| |
|Students convert repeating decimals into their fraction equivalent using patterns or algebraic reasoning. |
| |
|One method to find the fraction equivalent to a repeating decimal is shown below. |
| |
| |
|Example 1: |
| |
|Change 0.[pic] to a fraction. |
| |
|Let x = 0.444444….. |
|Multiply both sides so that the repeating digits will be in front of the decimal. In this example, one digit repeats so both sides are |
|multiplied by 10, giving 10x = 4.4444444…. |
|Subtract the original equation from the new equation. |
| |
|10x = 4.4444444…. |
|– x = 0.444444……. |
|9x = 4 |
| |
|Solve the equation to determine the equivalent fraction. |
| |
|9x = 4 |
|9 9 |
| |
|x = 4 |
|9 |
| |
|Additionally, students can investigate repeating patterns that occur when fractions have denominators of 9, 99, or 11. |
| |
|Example 2: |
| |
|[pic] is equivalent to 0.[pic], [pic] is equivalent to 0.[pic], etc. |
| |
|8.NS.2 Students locate rational and irrational numbers on the number line. Students compare and order rational and irrational numbers. |
|Students also recognize that square roots may be negative and written as - √28. |
| |
| |
| |
|Example 1: |
| |
|Compare [pic] and [pic] . |
|[pic] |
| |
| |
|Solution: Statements for the comparison could include: |
| |
|[pic] and [pic] are between the whole numbers 1 and 2 |
|[pic] is between 1.7 and 1.8 |
|[pic] is less than [pic] |
| |
|Additionally, students understand that the value of a square root can be approximated between integers and that nonperfect square roots are |
|irrational. |
| |
| |
|Example 2: |
| |
|Find an approximation of [pic] |
|Determine the perfect squares [pic]is between, which would be 25 and 36. |
|The square roots of 25 and 36 are 5 and 6 respectively, so we know that [pic] is between 5 and 6. |
|Since 28 is closer to 25, an estimate of the square root would be closer to 5. One method to get an estimate is to divide 3 (the distance |
|between 25 and 28) by 11 (the distance between the perfect squares of 25 and 36) to get 0.27. |
|The estimate of [pic] would be 5.27 (the actual is 5.29) |
| |
| | | |
|“Unpacked” Concepts |“Unwrapped” Skills |Cognition |
|(students need to know) |(students need to be able to do) |(DOK) |
| | | |
|8.EE.1 | | |
|Properties of exponents |I can use properties of exponents to simplify expressions |2 |
| | | |
| | | |
|8EE.2 | | |
|Perfect squares & cubes |I can solve and explain equations in the form of x2 = p and| |
| |x3 = p |2 |
|8.EE.3 | | |
|Scientific notation |I can represent very small or very large numbers in |2 |
| |scientific notation. | |
| |I can compare quantities written in scientific notation. | |
| | |3 |
|8.EE.4 | | |
|Computation in scientific notation and decimal form |I can compare and compute numbers in scientific notation |2 |
| |and decimal form. | |
| | | |
|Scientific notation on calculator |I can interpret how to read answer when the “E” appears con| |
| |the calculator. |2 |
|8.EE.7 | | |
|Linear equations with one, infinitely many, or no solution |I can provide examples of linear equations in one variable |3 |
| |with one, infinitely many or no solutions. | |
| |I can solve equations that include rational number |2 |
| |coefficients, expanding expressions, and combining like | |
| |terms. | |
| | | |
|8.NS.1 |I can classify numbers as rational or irrational and | |
|Rational or irrational numbers |explain why. |2 |
| | | |
|8.NS.2 | |2 |
|Comparison of irrational numbers |I can use the knowledge of square roots of perfect squares | |
| |to estimate value of other square roots. |2 |
| |I can order rational and irrational numbers on number line.| |
| |I can find approximate location of irrational numbers on a |2 |
| |number line. | |
| |Corresponding Big Ideas |
|Essential Questions | |
|8.EE.1 | |
|How can I apply properties of exponents to simplify expressions? |Students will apply laws of exponents to write equivalent expressions |
| |for a given expression. |
| | |
| | |
| | |
| | |
| | |
| | |
| | |
|8.EE.2 |Students will solve x2 = p, where p is a positive rational number |
|How can I solve equations of the form x2 = p? |represent the solution using the square root symbol, and can explain |
| |when and why the solution must include the ± (plus or minus) symbol. |
| |Students will solve x3 = p, where p is a positive rational number and |
| |represent the solution using the cube root symbol. The student knows |
| |that the cube root of a positive number is positive, and the cube root|
|How can I solve equations of the form x3 = p? |of a negative number is negative. |
| | |
| | |
| | |
|8EE.3 | |
|How can I represent very large or very small numbers in scientific |Students will represent very large and very small |
|notation? |quantities/measurements in scientific notation. |
| |Students will compare two quantities written in scientific notation |
| |and can reason how many times bigger/smaller one is than the other |
|How can I compare two quantities written in scientific notation? |without having to convert each number back into decimal form. |
| | |
|8.EE.4 | |
|How can I solve problems where both decimal and scientific notation |Students will solve problems that involve very large or very small |
|are used? |quantities where both decimal and scientific notation are used. |
| |Students will interpret how to read the answer when the “E” appears |
|How can I interpret the answer when “E” appears on the calculator? |when using a calculator to perform a calculation in which the answer |
| |will be a very large or very small number. |
| | |
|8.EE.7 | |
|How can I provide examples of linear equations with one, infinitely |Students will provide an example of a linear equation in one variable |
|many or no solution? |that has exactly one solution, infinitely many solutions, or no |
| |solution. |
| |Students will solve linear equations that include rational number |
|How can I solve equations that include rational number coefficients, |coefficients, expanding expressions and combining like terms. |
|expanding expressions, and combining like terms? | |
| | |
|8.NS.1 |Students will classify numbers as rational or irrational and explain |
|How can I classify numbers as rational or irrational and explain? |why. |
| | |
|8.NS.2 |Students will estimate value of square root of non perfect squares. |
|How can I use knowledge of square roots of perfect squares to estimate|Students will order rational and irrational numbers. |
|the value of other squares? |Students will approximate location of irrational numbers on the number|
|How can I order and compare rational or irrational from least to |line. |
|greatest? | |
|How can I approximate the location of irrational numbers on the number| |
|line? | |
| |
|Vocabulary |
| |
|laws of exponents, power, perfect squares, perfect cubes, root, square root, cube root, scientific notation, standard form of a number, |
|intersecting, parallel lines, coefficient, distributive property, like terms, real numbers, irrational numbers, rational numbers, integers, |
|whole numbers, natural numbers, radical, radicand, terminating decimals, repeating decimals, truncate |
| |
|Language Objectives |
|Key Vocabulary |
| | |
|8.EE.1 - 4 | |
|8.EE.7 |Define and give examples of vocabulary and expressions specific to this standard (properties, integer exponents, |
| |positive, negative, equivalent numerical expressions, raising to a power, square root, cube root, squaring, cubing, |
| |rational, irrational, inverse operations, scientific notation, distributive property, rational numbers, variables, |
| |equality, equation, solution, like terms, constant, value, linear equation, expanding expressions, coefficients, etc.) |
|Language Function |
| | |
| |SWBAT use sentence frames to explain why some equations have no solution. (Where variables cancel out, constants are not|
|8.EE.7 |equal.) |
| |SWBAT compare equations which have one solution (true equality) and multiple solutions. |
|Language Skills |
| | |
|8.EE.1 |SWBAT explain the properties of integer exponents to a partner. |
|8.EE.3 |SWBAT write a paragraph to explain how to interpret numbers written in scientific notation. |
| |SWBAT explain to a group how to use laws of exponents to multiply or divide numbers written in scientific notation. |
|8.EE.4 | |
| | |
|Language Structures |
|8.EE.2 |SWBAT write a paragraph to describe the relationship of square roots and squares and of cube roots and cubes. |
| |SWBAT use sequence words and phrases to explain the step-by-step process of solving linear equations, including those |
|8.EE.7 |with rational coefficients, expanding expressions using distributive property and collecting like terms. |
| | |
|Language Tasks |
|8.EE.7 |SWBAT transform equations into simpler forms until an equivalent equation results and explain the process. |
|8.EE.7 |SWBAT transform equations into simpler forms until an equivalent equation results and explain the process |
|Language Learning Strategies |
|8.EE.7 |SWBAT interpret how the graph of the solution of a linear equation represents the coordinates of the point where the two |
| |lines would intersect. |
| |SWBAT explain why the graph of the solution of a linear equation represents a pair of parallel lines. |
|8.EE.7 |SWBAT interpret the graph of an equation with infinitely many solutions (same line). |
| | |
| | |
|8.EE.7 | |
| |
|Information and Technology Standards |
| |
|8.TT.1.2 Use appropriate technology tools and other resources to organize information (e.g. graphic organizers, databases, spreadsheets, and |
|desktop publishing). |
|8.RP.1.1 Implement a project-based activity collaboratively. |
|8.RP.1.2 Implement a project-based activity independently. |
| |
|Instructional Resources and Materials |
|Physical |Technology-Based |
| | |
|Connected Math 2 Series |WSFCS Math Wiki |
|Common Core Investigation 1, 2 | |
|Growing, Growing, Growing, Inv.1 (ACE problems, select applicable) |NCDPI Wikispaces Eighth Grade |
|Thinking With Mathematical Models, Inv.2 | |
|Say It With Symbols, Inv. 1-4 (skip 3.3, 3.4) (ACE problems, select |MARS |
|applicable) | |
|Looking for Pythagoras, Inv. 2 |Georgia Unit |
| | |
|Partners in Math Materials |Illustrative Math |
|Scientific Notation & Standard Form | |
|Set of Real Numbers |Illuminations |
|Number Sort | |
|Halfway Numbers | |
|Exactly Square | |
|Ranking Rationals | |
|Scientific Shuffle | |
| | |
|Lessons for Learning (DPI) | |
|Real Number Race | |
|The Laundry Problem | |
| | |
|Mathematics Assessment Project (MARS) | |
|Applying Properties of Exponents | |
|Estimating Length Using Scientific Notation | |
|Repeating Decimals | |
|Solving Linear Equations in One Variable | |
|Building and Solving Equations 1 | |
|100 People, task | |
|A Million Dollars, task | |
|How Old Are They, task | |
|Ponzi Pyramid Schemes, HS task | |
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